EP3040253A1 - Appareil de commande de direction - Google Patents

Appareil de commande de direction Download PDF

Info

Publication number: EP3040253A1
Authority: EP; European Patent Office
Prior art keywords: angle; value; processing circuit; tire; rotation
Prior art date: 2014-12-24
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Withdrawn

Application number

EP15201378.5A

Other languages

German (de)

English (en)

Inventor

Takashi Kodera

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

JTEKT Corp

Original Assignee

JTEKT Corp

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

2014-12-24

Filing date

2015-12-18

Publication date

2016-07-06

2015-12-18 Application filed by JTEKT Corp filed Critical JTEKT Corp

2016-07-06 Publication of EP3040253A1 publication Critical patent/EP3040253A1/fr

Status Withdrawn legal-status Critical Current

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Classifications

- B—PERFORMING OPERATIONS; TRANSPORTING
- B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
- B62D—MOTOR VEHICLES; TRAILERS
- B62D5/00—Power-assisted or power-driven steering
- B62D5/04—Power-assisted or power-driven steering electrical, e.g. using an electric servo-motor connected to, or forming part of, the steering gear
- B62D5/0457—Power-assisted or power-driven steering electrical, e.g. using an electric servo-motor connected to, or forming part of, the steering gear characterised by control features of the drive means as such
- B62D5/046—Controlling the motor
- B62D5/0469—End-of-stroke control
- B—PERFORMING OPERATIONS; TRANSPORTING
- B62—LAND VEHICLES FOR TRAVELLING OTHERWISE THAN ON RAILS
- B62D—MOTOR VEHICLES; TRAILERS
- B62D6/00—Arrangements for automatically controlling steering depending on driving conditions sensed and responded to, e.g. control circuits
- B62D6/001—Arrangements for automatically controlling steering depending on driving conditions sensed and responded to, e.g. control circuits the torque NOT being among the input parameters

Definitions

the invention relates to a steering control apparatus that manipulates an electric power conversion circuit connected to a synchronous motor in order to generate a steering assist force using a torque of the synchronous motor.
a steering operation of increasing a tire angle (a steered angle that is the angle of steered wheels) to a given value or larger is inhibited.
a steering operation of increasing a tire angle (a steered angle that is the angle of steered wheels) to a given value or larger is inhibited.
an end of a rack shaft comes into contact with a rack housing to inhibit a steering operation of further increasing the tire angle (see Paragraph [0006] in Japanese Patent No. 5050421 ).
the electric power steering system (steering control apparatus) may be subjected to impact.
the impact is desirably mitigated.
a steering control apparatus includes:
the assist processing circuit outputs the manipulation signal to the electric power conversion circuit, and the electric power conversion circuit is manipulated by the manipulation signal to control the torque of the synchronous motor.
the coordinate transformation is executed by the transformation processing circuit on the intermediate variable obtained during the calculation of the manipulation signal.
the change rate of the rotation speed used by the transformation processing circuit is changed from the change rate of the rotation speed acquired by the rotation-angle acquisition processing circuit when the one of the absolute values acquired by the tire-angle acquisition processing circuit is equal to or higher than the prescribed value.
the manipulation signal does not correspond to rotation of the synchronous motor, and thus, the phases of currents flowing through the synchronous motor are changed unlike in a case where the change rate remains the same.
the torque of the synchronous motor changes. Consequently, when the absolute value of the tire angle increases, a force can be suppressed which is applied to a steering system and which acts to increase the absolute value of the tire angle.
the prescribed value may be set to one of the tire angle and the equivalent value thereof the tire angle being a tire angle the absolute value of which is smaller than a maximum value of the tire angle by a predetermined value.
the angle manipulation processing circuit changes the change rate of the control angle from the change rate of the rotation angle before the absolute value of the tire angle reaches the maximum value thereof.
the synchronous motor is suppressed from generating a torque that acts to increase the absolute value of the tire angle before the absolute value of the tire angle reaches the maximum value thereof.
the angle manipulation processing circuit may control the change rate of the control angle such that the torque of the synchronous motor has such a sign that reduces one of the absolute value of the tire angle and the absolute value of the equivalent value thereof when one of the absolute value of the tire angle and the absolute value of the equivalent value thereof further increases after start of processing of changing the change rate of the control angle.
the sign of the torque of the synchronous motor is reversed when the one of the absolute values acquired by the tire-angle acquisition processing circuit further increases after start of the processing of changing the change rate of the control angle.
a steering torque needs to be sufficient to cancel the torque of the synchronous motor. Consequently, a further increase in the absolute value of the tire angle can be suitably suppressed.
the angle manipulation processing circuit may fix the control angle until the control angle lags, by a predetermined lag angle amount, behind the rotation angle acquired by the rotation-angle acquisition processing circuit, afterwards, by causing the control angle to be lagged behind by the predetermined lag angle amount, the control angle is updated according to the change rate of the rotation angle acquired by the rotation-angle acquisition processing circuit, when the one of the absolute value of the tire angle and the absolute value of the equivalent value thereof is equal to or larger than the prescribed value.
the predetermined lag angle amount is a lag angle amount at which the control angle falls into an angle area where the synchronous motor generates a torque having the sign that is opposite to the sign of a torque obtained when the absolute value of the tire angle and the absolute value of the equivalent value thereof is equal to or larger than the prescribed value.
the control angle is fixed when the one of the absolute values acquired by the tire-angle acquisition processing circuit is equal to or larger than the prescribed value. Consequently, the torque of the synchronous motor changes.
the torque of the synchronous motor decreases when the rotation angle acquired by the rotation-angle acquisition processing circuit changes and accordingly the lag angle amount of the control angle used by the transformation processing circuit increases.
a further increase in lag angle amount reverses the sign of the torque of the synchronous motor.
the lag angle amount is set to a predetermined value to update the rotation angle used by the transformation processing circuit according to the change rate of the rotation angle acquired by the rotation-angle acquisition processing circuit. As a result, the sign of the torque remains reversed.
the angle manipulation processing circuit may fix the control angle until the control angle becomes equal to the rotation angle acquired by the rotation-angle acquisition processing circuit, afterwards may update the control angle according to the change rate of the acquired rotation angle by causing the control angle equal to the rotation angle.
the steering control apparatus further may include a current feedback control circuit that calculates a feedback manipulative value in a rotating coordinate system that is used to coincide a value, in the rotating coordinate system, of a current flowing through the synchronous motor with a command value
the transformation processing circuit includes: a rotating-transformation processing circuit that uses a detected value of the current flowing through the synchronous motor as an input to transform the detected value into a value in the rotating coordinate system; and a fixed-transformation processing circuit that transforms, into a value in a fixed coordinate system, a command voltage that is a command value for a voltage applied to the synchronous motor by the electric power conversion circuit and that is the command value set according to the feedback manipulative value.
the detected value of the current transformed by the rotating-transformation processing circuit is input to the current feedback control circuit, which then calculates the manipulative value that is used to feed the input value back to the command value.
the fixed-transformation processing circuit converts the command voltage into a value in the fixed coordinate system.
the command voltage is the calculated manipulative value itself, a value resulting from addition of an open-loop manipulative value to the calculated manipulative value, or the like. Based on the command voltage in the fixed coordinate system, the manipulation signal for the electric power conversion circuit is generated.
the steering control apparatus further includes a limitation processing circuit that limits a current value of the synchronous motor equal to or smaller than a limit current value when the one of the absolute value of the tire angle and the absolute value of the equivalent value thereof is equal to or larger than the prescribed value.
the current value of the synchronous motor is limited to the limit current value or smaller by the limitation processing circuit.
the amount of heat generated by the synchronous motor, the electric power conversion circuit, and the like can be limited.
the limit current value may be a fixed value.
This configuration which uses the fixed value as the limit current value, allows the limitation processing circuit to be configured simply as compared to a configuration in which the limit current value varies according to a certain parameter.
the limitation processing circuit variably may set the limit current value according to a detected value of the steering torque.
a torque that acts to increase the absolute value of the tire angle is set according to the steering torque and the torque of the synchronous motor.
the limit current value appropriate to suppress the absolute value of the tire angle from further increasing is also set according to the steering torque.
the limitation processing circuit variably may set the limit current value, and takes into account at least one of temperatures of the synchronous motor, the electric power conversion circuit, and a manipulation circuit for the electric power conversion circuit in variably setting of the limit current value.
the limit current value is set based on the at least one of the temperatures of the synchronous motor, the electric power conversion circuit, and the manipulation circuit for the electric power conversion circuit.
the limit current value can be made appropriate to suppress the at least one of the temperatures from elevating excessively.
An electric power steering system (EPS 10) depicted in FIG. 1 includes a steering control apparatus in a first embodiment.
EPS 10 a steering shaft 14 to which a steering wheel 12 is fixed is coupled to a rack shaft 18 via a rack and pinion mechanism 16. Rotation of the steering shaft 14 due to a steering operation is converted into a reciprocating linear motion of the rack shaft 18 by the rack and pinion mechanism 16.
the steering shaft 14 in the present embodiment includes a column shaft 14a and an intermediate shaft 14b, and the steering shaft 14 is coupled to a pinion shaft 14c.
the EPS 10 includes a motor 30 that apples an assist force used to assist the steering operation to a steering system, and a control apparatus (ECU 40) that controls the motor 30.
the motor 30 is coupled to the column shaft 14a via a speed reducer 34. The rotation speed of the motor 30 is reduced and the resultant rotation is transmitted to the column shaft 14a, so that the assist force corresponding to the torque of the motor 30 is applied to the steering system.
the motor 30 is assumed to be a surface permanent magnet synchronous motor (SPMSM).
the motor 30 includes a resolver 32 that detects a rotation angle ⁇ m of a rotating shaft of the motor 30.
the motor 30 is connected to a battery 39 via an inverter INV.
the inverter INV is a circuit that allows for electrical connection and disconnection between each of a positive electrode and a negative electrode of the battery 39 and three terminals of the motor 30.
MOS field effect transistors included in the inverter INV and connected to the respective terminals of the motor 30 are denoted by reference characters u, v, and w.
An upper arm is denoted by reference character p and a lower arm is denoted by reference character n.
Reference characters u, v, and w are hereinafter collectively represented as ⁇ , and reference characters p and n are hereinafter collectively represented as #.
the inverter INV includes a series-connection member including a switching element S ⁇ p that allows for electrical connection and disconnection between the positive electrode of the battery 39 and the terminals of the motor 30 and a switching element S ⁇ n that allows for electrical connection and disconnection between the negative electrode of the battery 39 and the terminals of the motor 30.
the motor 30, the inverter INV, and the ECU 40 are packaged into a single motor unit MCU.
the ECU 40 receives the rotation angle ⁇ m detected by the resolver 32, a steering torque Trq detected by a torque sensor 42, a vehicle speed V detected by a vehicle speed sensor 46, currents iu, iv, and iw from the motor 30 detected by a current sensor 48. Based on these detected values, the ECU 40 outputs a manipulation signal g ⁇ # to the inverter INV connected to the motor 30 so as to manipulate the inverter INV and thus control the torque of the motor 30. That is, the ECU 40 is a manipulation circuit for the inverter INV.
the rotation angle ⁇ m is an electrical angle.
FIG. 2 depicts a block diagram of the ECU 40.
Each control circuit depicted in FIG. 2 is implemented by a microcomputer provided in the ECU 40 by executing a control program.
a target steering torque setting circuit 50 sets a target steering torque Trq* that is a command value for the torque of the motor 30 based on the steering torque Trq and the vehicle speed V.
a command current setting circuit 52 sets command currents id* and iq* on a d axis and a q axis based on the target steering torque Trq*.
the command current setting circuit 52 sets the command current iq* on the q axis such that the absolute value of the command current iq* increases as the absolute value of the target steering torque Trq* increases.
the command current setting circuit 52 sets the command current id* on the d axis to zero.
a dq transformation circuit 54 transforms three-phase currents iu, iv, and iw detected by the current sensor 48 into currents id and iq on the d and q axes.
a deviation calculation circuit 56 outputs a value resulting from subtraction of the current id from the command current id* on the d axis.
a deviation calculation circuit 58 outputs a value resulting from subtraction of the current iq from the command current iq* on the q axis.
a current feedback control circuit 60 calculates a command current vd* on the d axis as a manipulative value that is used to feed the current id on the d axis back to command current id*.
a current feedback control circuit 62 calculates a command current vq* on the q axis as a manipulative value that is used to feed the current iq on the q axis back to command current iq*.
each of the current feedback control circuits 60 and 62 is configured using a proportional element and an integral element.
An output from each of the current feedback control circuits 60 and 62 is the sum of an output value from the proportional element and an output value from the integral element that are obtained using, as an input, an output value from a corresponding one of the deviation calculation circuits 56 and 58.
a uvw transformation circuit 64 transforms the command voltages vd* and vq* on the d and q axes into three-phase command voltages vu*, vv*, and vw*.
a PWM transformation circuit 66 generates three-phase PWM signals gu, gv, and gw based on the three-phase command voltages vu*, vv*, and vw*.
a PWM signal g ⁇ defines an on operation period for the switching element S ⁇ p of the upper arm using a logical H period except for a dead time.
a dead-time generation circuit 68 generates the manipulation signal g ⁇ # for the switching element S ⁇ # based on the PWM signal g ⁇ , and outputs the manipulation signal g ⁇ # to the inverter INV.
a dead time is applied to the manipulation signal g ⁇ # such that, before a first switching element of the switching element S ⁇ p of the upper arm and the switching element S ⁇ n on the lower arm that has been turned off is turned on, a second switching element is turned off.
a rotation-angle acquisition processing circuit 69 acquires the rotation angle ⁇ m of the motor detected by the resolver 32. This process may involve, for example, sampling an output signal from the resolver 32.
An angle manipulation processing circuit 70 normally outputs the rotation angle ⁇ m acquired by the rotation-angle acquisition processing circuit 69 to the dq transformation circuit 54 and the uvw transformation circuit 64 as a rotation angle used for a coordinate transformation by the dq transformation circuit 54 and the uvw transformation circuit 64 (this rotation angle is hereinafter referred to as a control angle ⁇ c).
the angle manipulation processing circuit 70 executes processing of changing a change rate of the control angle ⁇ c with respect to a change rate of the rotation angle ⁇ m based on output values from a tire-angle acquisition processing circuit 74 and a speed calculation circuit 72. This processing will be described below.
the speed calculation circuit 72 calculates an electrical angular speed (rotation speed ⁇ ) based on the rotation angle ⁇ m of the motor.
the tire-angle acquisition processing circuit 74 acquires a tire angle ⁇ t of the steered wheels 22.
the tire-angle acquisition processing circuit 74 independently calculates the tire angle ⁇ t based on the rotation angle ⁇ m. This can be achieved by executing an integral processing on the rotation angle ⁇ m.
the rotation angle ⁇ m is a parameter with a value ranging from 0° to 360°, but the absolute value of the tire angle ⁇ t gradually increases while the motor 30 is making a plurality of rotations, and thus there is no one-to-one correspondence between the rotation angle ⁇ m of the motor and the tire angle ⁇ t.
the tire-angle acquisition processing circuit 74 integrates the rotation angle ⁇ m to calculate the tire angle ⁇ t.
the maximum value of the absolute value of the tire angle ⁇ t is smaller than 360°. Since the steering control apparatus is provided with the speed reducer 34, the motor 30 makes a plurality of rotations before the absolute value of the tire angle ⁇ t is maximized.
the tire-angle acquisition processing circuit 74 multiplies the integral value of the rotation angle ⁇ m by, for example, a coefficient corresponding to a speed reduction ratio of the speed reducer 34.
FIG. 3 illustrates a procedure of angle manipulation processing executed mainly by the angle manipulation processing circuit 70.
the processing is repeated at an update cycle for the rotation angle ⁇ m.
the update cycle for the rotation angle ⁇ m is longer than a sampling cycle for the currents iu, iv, and iw.
the rotation-angle acquisition processing circuit 69 first acquires the rotation angle ⁇ m (S10). Subsequently, the angle manipulation processing circuit 70 determines whether or not a change flag F is 1 (S12).
the change flag F indicates whether or not processing of changing the control angle ⁇ c with respect to the rotation angle ⁇ m to suppress an increase in the absolute value
the change flag F of 1 indicates that the changing processing has been executed, whereas the change flag F of 0 indicates that the changing processing has not been executed.
the tire-angle acquisition processing circuit 74 acquires the tire angle ⁇ t (S 14). Subsequently, the angle manipulation processing circuit 70 determines whether or not the absolute value of the tire angle ⁇ t is equal to or larger than a prescribed value ⁇ tth (S116). This process is intended to determine whether or not an increased absolute value of the tire angle ⁇ t has reduced the distance between the end of the rack shaft 18 and the rack housing facing the end. This is in turn intended to execute the fixation processing, which is a process of limiting the torque of the motor 30, before end contact occurs, that is, before the end of the rack shaft 18 comes into contact with the rack housing facing the end.
the prescribed value ⁇ tth is set to such a value that end contact does not occur even if the motor 30 further rotates by 180° or more. Specifically, in the present embodiment, the prescribed value ⁇ tth is set to such a value that end contact does not occur even if the motor 30 further rotates by 360°.
the angle manipulation processing circuit 70 determines that the absolute value is smaller than the prescribed value ⁇ tth (S16: NO), the angle manipulation processing circuit 70 updates the control angle ⁇ c to the value of the rotation angle ⁇ m (S18). Thus, the control angle ⁇ c is changed according to the change rate of the rotation angle ⁇ m. On the other hand, if the angle manipulation processing circuit 70 determines that the absolute value is equal to or larger than the prescribed value ⁇ tth (S16: YES), the angle manipulation processing circuit 70 sets the change flag F to 1 (S20).
step S12 determines whether the sign of the rotation speed ⁇ is equal to that of the tire angle ⁇ t (S22). This process is intended to determine whether or not the absolute value of the tire angle ⁇ t has decreased. If the angle manipulation processing circuit 70 determines that the sign of the rotation speed ⁇ is equal to that of the tire angle ⁇ t (S22: YES), the angle manipulation processing circuit 70 determines whether or not a value resulting from subtraction of the control angle ⁇ c from the rotation angle ⁇ m is 180° (S24). This process is intended to determine whether or not the fixation processing for the control angle ⁇ c should be ended.
step S26 the angle manipulation processing circuit 70 executes the processing of fixing the control angle ⁇ c (S26).
the control angle ⁇ c is lagged behind the rotation angle ⁇ m.
the torque of the motor 30 gradually decreases as the amount of the lag angle increases. That is, the current feedback control circuits 60 and 62 control the currents id and iq such that the current id coincides with id* and such that the currentiq coincides with iq*.
the command current id* is equal to zero and the command current iq* is larger than zero.
the currents id and iq input to the current feedback control circuits 60 and 62 lag behind currents actually flowing through the motor 30.
the motor 30 is an SPMSM in thus embodiment.
step S24 the angle manipulation processing circuit 70 stops the fixation processing and updates the control angle ⁇ c using an amount equal to an amount that is used to update the rotation angle ⁇ m (S28). Consequently, the amount by which the control angle ⁇ c lags behind the rotation angle ⁇ m is maintained at 180°. This is intended to maximize the torque of the motor 30 when the torque has such a sign that the torque reduces the absolute value of the tire angle ⁇ t.
Processing of continuing the fixation processing until the difference between the rotation angle ⁇ m and the control angle ⁇ c becomes 180° controls the change rate of the control angle ⁇ c to zero so as to reverse the sign of the torque of the motor 30.
the angle manipulation processing circuit 70 determines whether or not the sign of the rotation speed ⁇ is different from that of the tire angle ⁇ t (S22: NO). This process is intended to determine whether or not the fixation processing for the control angle ⁇ c described below should be ended, which is a process executed as a result of the negative determination in step S22. If the angle manipulation processing circuit 70 determines that the rotation angle ⁇ m and the control angle ⁇ c are not equal to each other (S30: NO), the angle manipulation processing circuit 70 executes the fixation processing of fixing the control angle ⁇ c (S32).
This process is intended to wait until the control angle ⁇ c becomes equal to the rotation angle ⁇ m when the control angle ⁇ c is different in value from the rotation angle ⁇ m as a result of the fixation processing in the above-described step S26. That is, the rotation angle ⁇ m periodically changes between 0° and 360° as the motor 30 rotates, and thus, the fixation of the control angle ⁇ c is expected to eventually make the control angle ⁇ c equal to the rotation angle ⁇ m as the rotation angle ⁇ m is repeatedly updated.
the angle manipulation processing circuit 70 determines that the rotation angle ⁇ m and the control angle ⁇ c are equal to each other (S30: YES), the angle manipulation processing circuit 70 sets the change flag to zero (S34). In the processing in FIG. 3 that will be performed in the subsequent control cycle, the change rate of the control angle ⁇ c is equal to that of the rotation angle ⁇ m, and the control angle ⁇ c is equal to the rotation angle ⁇ m.
the angle manipulation processing circuit 70 temporarily ends the series of processes.
FIG. 4 illustrates an example of transition of the control angle ⁇ c resulting from the processing in FIG. 3 .
the axis of abscissas represents the rotation angle ⁇ m, and values from 0° to 360° are periodically repeated on the axis of abscissas.
the control angle ⁇ c is equal to the rotation angle ⁇ m of the motor and periodically changes between 0° and 360° as the rotation angle ⁇ m changes.
the fixation processing in step S26 is executed to fix the control angle ⁇ c.
the control angle ⁇ c lags behind the rotation angle ⁇ m.
the current on the q axis included in the currents flowing through the motor 30 and contributing to the torque, decreases, and the current on the d axis, which is a reactive current, increases. Consequently, the torque of the motor 30 gradually decreases as the rotation angle ⁇ m changes.
FIG. 5 illustrates the relation between the torque of the motor 30 and the difference between the rotation angle ⁇ m and the control angle ⁇ c. As illustrated in FIG.
the sign of the torque of the motor 30 is reversed when the amount by which the control angle ⁇ c lags behind the rotation angle ⁇ m exceeds 90°, and the torque of the motor 30 has an absolute value equal to the target steering torque Trq* when the amount of the lag angle is 180°.
the fixation processing is ended.
the control angle ⁇ c is updated in the processing in the above-described step S28, according to the amount by which the rotation angle ⁇ m is updated.
the control angle ⁇ c is set such that the change rate of the control angle ⁇ c is equal to that of the rotation angle ⁇ m.
the motor 30 continuously applies the torque that cancels the steering torque Trq to the steering system.
step S32 allows the fixation processing for the control angle ⁇ c to be started (period a2 in FIG. 4 ).
the control angle ⁇ c is changed according to the rotation angle ⁇ m (period a3 in FIG. 4 ) because a 180° change in rotation angle ⁇ m makes the control angle ⁇ c equal to the rotation angle ⁇ m.
FIG. 6 illustrates the relation between the transition of the absolute value
the user increases the steering torque Trq if the user attempts to increase the absolute value
the torque of the motor 30 immediately shifts so that the torque reduces the absolute value
the user needs to further increase the steering torque Trq in order so as to increase the absolute value
FIG. 7 depicts a control block diagram of the ECU 40 according to a second embodiment.
circuits corresponding to those in FIG. 2 are denoted by the same reference numerals for convenience.
the target steering torque Trq* set by the target steering torque setting circuit 50 is input to a limitation processing circuit 80.
the limitation processing circuit 80 corrects the target steering torque Trq* and outputs the corrected target steering torque Trq* to the command current setting circuit 52.
the command current setting circuit 52 sets the command current iq* based on the corrected value of the target steering torque Trq*.
the command current iq* is limited to a limit current value.
the limitation processing circuit 80 limits the target steering torque Trq* to a limit torque Tg over a period of time when the change flag is kept at 1 by the angle manipulation processing circuit 70.
the limit torque Tg is set to an estimated maximum value of the steering torque Trq input to the steering wheel 12 by the user.
FIG. 8 illustrates a procedure for angle manipulation processing and limitation processing mainly executed by the limitation processing circuit 80 and the angle manipulation processing circuit 70.
processes corresponding to those in FIG. 3 are denoted by the same step numbers for convenience.
the angle manipulation processing circuit 70 determines that the absolute value
the limitation processing circuit 80 executes guard processing on the target steering torque Trq* by use of the limit torque Tg (S20a).
the maximum value of the absolute value of the torque of the motor 30 is limited to the limit torque Tg. Accordingly, the torque of the motor 30 obtained when the amount by which the control angle ⁇ c lags behind the rotation angle ⁇ m is 180° is -Tg.
the limit torque Tg is the estimated maximum value of the steering torque Trq as described above.
the user cannot turn the steering wheel 12 in such a direction that the absolute value of the tire angle ⁇ t increases.
This configuration limits the command current iq* set by the command current setting circuit 52 as compared to a configuration in which the guard processing is not executed on the target steering torque Trq*. Thus, the absolute values of the currents flowing through the motor 30 are limited. This suppresses heat generation by the motor 30, the inverter INV, and the like.
FIG. 10 depicts a control block diagram of the ECU 40 according to a third embodiment.
circuits corresponding to those in FIG. 7 are denoted by the same reference numerals for convenience.
the limitation processing circuit 80 variably sets the limit torque Tg according to the currents iu, iv, and iw flowing through the motor 30 and the steering torque Trq.
the limit torque Tg is variable according to the steering torque Trq because a torque needed to suitably suppress an increase in the absolute value of the tire angle ⁇ t is set according to the steering torque Trq.
the limit torque Tg may be set equal to the steering torque Trq multiplied by a predetermined number (> 0).
the currents iu, iv, and iw are parameters correlated with the temperature of the motor 30 or inverter INV
the motor 30 and the inverter INV, in combination with the ECU 40 are packaged into the single motor unit MCU, and thus, the currents iu, iv, and iw also serve as parameters correlated with the temperature of the ECU 40.
the temperatures of the motor 30, the inverter INV, and the ECU 40 increase as amplitude values of the currents iu, iv, and iw increase, and the limit torque Tg is set to a small value.
the predetermined multiplier is desirably one or larger, but may be smaller than one if the temperatures are estimated to be excessively high.
the above embodiments may be modified as follows for implementation.
the tire-angle acquisition processing circuit is not limited to the calculation of the tire angle ⁇ t based on the integral value of the rotation angle ⁇ m of the motor.
a sensor that detects a steering angle may be provided so that the tire angle ⁇ t is calculated based on the integral value of detected values from the sensor.
the integral value itself may be utilized as an equivalent value of the tire angle ⁇ t.
a gear ratio varying apparatus that can vary a gear ratio that sets the amount of change in tire angle with respect to the amount of change in steering angle
a prescribed value to be compared with the equivalent value of the tire angle ⁇ t is variably set, so that whether the absolute value of the tire angle ⁇ t is equal to or larger than the prescribed value can be determined regardless of the gear ratio.
the equivalent value of the tire angle is not limited to the integral value of the rotation angle ⁇ m or the steering angle.
the equivalent value may be, for example, a detected value from a sensor that detects the distance between the end of the rack shaft 18 and the rack housing. In this case, the tire-angle acquisition processing circuit only acquires the detected value and executes no calculation processing.
the resolver 32 outputs the detected value of the electrical angle, and the rotation-angle acquisition processing circuit (69) acquires the detected value in step S10.
the present invention is not limited to this.
the resolver 32 may output the detected value of a mechanical radian, and the ECU 40 may calculate an electrical angle from the mechanical radian.
the transformation circuits (54 and 64) may be modified as follows. For example, if no current feedback control is performed and the command voltages vd* and vq* are set as manipulative values that allow open-loop control to be performed on the command currents id* and iq*, the uvw transformation circuit 64 may be provided which serves as a fixed-transformation processing circuit that transforms the command voltages vd* and vq* into values in a fixed coordinate system, and the dq transformation circuit 54 that serves as a rotating-transformation processing circuit may be omitted.
the uvw transformation circuit 64 that serves as a fixed-transformation processing circuit may transform the corrected values.
the steering control apparatus including both the dq transformation circuit 54 that serves as a rotating-transformation processing circuit and the uvw transformation circuit 64 that serves as a fixed-transformation processing circuit is not limited to the steering control apparatuses that perform the current feedback control in the above forms.
model predictive control may be performed by predicting, given each of switching modes for the inverter INV, currents that will flow through the motor 30 based on the currents id and iq output by the dq transformation circuit 54 so that an actual switching mode is determined based on the result of the prediction.
the rotation angle (control angle) is used to predict the currents.
the rotation angle may be obtained by advancing the rotation angle ⁇ m for prediction, and changing the change rate of the rotation angle produces effects according to the above-described embodiments.
the control angle ⁇ c has a fixed value until the control angle ⁇ c lags behind the rotation angle ⁇ m by 180° in the above-described embodiments.
the present invention is not limited to this.
the control angle ⁇ c may have a fixed value until the lag angle amount reaches A° (90 ⁇ A ⁇ 270), and may subsequently be updated by an amount equal to the amount by which the rotation angle ⁇ m is updated.
the control angle ⁇ c when the sign of the rotation speed ⁇ the motor 30 is reversed, the control angle ⁇ c is fixed until the control angle ⁇ c becomes equal to the rotation speed ⁇ m.
the present invention is not limited to this.
the control angle ⁇ c may be immediately made equal to the rotation speed ⁇ m.
the limitation processing circuit estimates the temperature of the motor 30, the inverter INV, or the manipulation circuit (ECU 40) based on the currents flowing through the motor 30.
the present invention is not limited to this.
detected values from a temperature sensor may be used.
the absolute value of the target steering torque Trq* is directly controlled.
the present invention is not limited to this.
the absolute value of the command value for the current flowing through the motor 30, such as the absolute value of the command current iq* on the q axis, may be directly controlled.
the prescribed value ⁇ tth is set to a value smaller than the maximum absolute value of the tire angle ⁇ t by a predetermined value, and the predetermined value is 360° or larger.
the present invention is not limited to this.
the prescribed value ⁇ tth may be the maximum value.
the motor 30 may rotate slightly even after the prescribed value ⁇ tth is reached. In this case, effects according to the above-described embodiments can be produced.
the command current id* on the d axis is zero in the above-described embodiments.
the present invention is not limited to this.
the control angle ⁇ c is manipulated to change the angle between the q axis and a command current vector (id*, iq*) such that no torque is generated by the motor 30 when the angle is 90°.
the angle is between 90° and 270°, the sign of the torque of the motor 30 is opposite to that of the steering torque Trq.
the synchronous motor is not limited to the SPMSM but may be, for example, an IPMSM. Moreover, the synchronous motor may be a wound-field synchronous motor.
the electric power conversion circuit is not limited to the inverter INV according to the above-described embodiments but may be a three-level inverter.
the electric power conversion circuit does not necessarily include the switching element SY# that allows for electrical connection and disconnection between each of a positive and a negative electrode of a DC voltage source (battery 39) and terminals of an electric rotating machine.
each of the terminals of the electric rotating machine may connect to a circuit having a circuit configuration similar to that of a well-known DCDC converter. In this case as well, output voltages from the converters are changed at a high speed so as to be set to a command voltage v ⁇ *, which allows producing effects according to the above-described embodiments.
the motor unit is not limited to the single motor unit into which the motor 30, the inverter INV, and the ECU 40 are packaged.
the motor 30 and the inverter INV may be packaged into a unit, and another housing may be provided for the ECU 40.
the inverter INV and the ECU 40 may be packaged into a unit, and the motor 30 may be provided separately from the unit.

Landscapes

Engineering & Computer Science (AREA)
Chemical & Material Sciences (AREA)
Combustion & Propulsion (AREA)
Transportation (AREA)
Mechanical Engineering (AREA)
Steering Control In Accordance With Driving Conditions (AREA)
Power Steering Mechanism (AREA)
Control Of Ac Motors In General (AREA)
Control Of Motors That Do Not Use Commutators (AREA)

EP15201378.5A 2014-12-24 2015-12-18 Appareil de commande de direction Withdrawn EP3040253A1 (fr)

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
JP2014260915A JP2016120789A (ja)	2014-12-24	2014-12-24	操舵アシスト装置

Publications (1)

Publication Number	Publication Date
EP3040253A1 true EP3040253A1 (fr)	2016-07-06

Family

ID=54979488

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
EP15201378.5A Withdrawn EP3040253A1 (fr)	2014-12-24	2015-12-18	Appareil de commande de direction

Country Status (4)

Country	Link
US (1)	US9650067B2 (fr)
EP (1)	EP3040253A1 (fr)
JP (1)	JP2016120789A (fr)
CN (1)	CN105730502A (fr)

Families Citing this family (6)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
WO2017119214A1 (fr) *	2016-01-08	2017-07-13	株式会社村田製作所	Dispositif de conversion d'énergie électrique
EP3460985B1 (fr) *	2016-07-20	2021-01-06	NSK Ltd.	Dispositif de direction assistée électrique
JP6809093B2 (ja)	2016-09-29	2021-01-06	株式会社デンソー	モータ制御装置およびこれを用いた電動パワーステアリング装置
US20200017139A1 (en) *	2018-07-12	2020-01-16	Steering Solutions Ip Holding Corporation	Rack force estimation for steering systems
JP7110787B2 (ja) *	2018-07-23	2022-08-02	株式会社ジェイテクト	操舵制御装置
JP7259574B2 (ja) *	2019-06-17	2023-04-18	株式会社ジェイテクト	制御装置、および転舵装置

Citations (3)

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JPH0550421B2 (fr)	1986-12-03	1993-07-29	Fuji Photo Film Co Ltd
DE19713576A1 (de) *	1997-04-02	1998-10-08	Bosch Gmbh Robert	Verfahren und Vorrichtung zum Betrieb eines Lenksystems für ein Kraftfahrzeug
EP1708355A1 (fr) *	2004-01-13	2006-10-04	NSK Ltd.,	Dispositif pour commander un dispositif motorise de direction assistee

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JP5050421B2 (ja)	2005-07-12	2012-10-17	日本精工株式会社	電動パワーステアリング装置の制御装置

2014
- 2014-12-24 JP JP2014260915A patent/JP2016120789A/ja active Pending
2015
- 2015-12-17 US US14/972,634 patent/US9650067B2/en not_active Expired - Fee Related
- 2015-12-18 EP EP15201378.5A patent/EP3040253A1/fr not_active Withdrawn
- 2015-12-22 CN CN201510969132.XA patent/CN105730502A/zh active Pending

Patent Citations (3)

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JPH0550421B2 (fr)	1986-12-03	1993-07-29	Fuji Photo Film Co Ltd
DE19713576A1 (de) *	1997-04-02	1998-10-08	Bosch Gmbh Robert	Verfahren und Vorrichtung zum Betrieb eines Lenksystems für ein Kraftfahrzeug
EP1708355A1 (fr) *	2004-01-13	2006-10-04	NSK Ltd.,	Dispositif pour commander un dispositif motorise de direction assistee

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Publication number	Publication date
US9650067B2 (en)	2017-05-16
JP2016120789A (ja)	2016-07-07
CN105730502A (zh)	2016-07-06
US20160185384A1 (en)	2016-06-30

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2017-07-19	18W	Application withdrawn	Effective date: 20170613

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